Trnsys Tutorial

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TRNSYS 17

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i m u l a t i o n p r o g r a m

V o l u m e 1

G e t t i n g S t a r t e d

Solar Energy Laboratory, Univ. of Wisconsin-Madison http://sel.me.wisc.edu/trnsys

TRANSSOLAR Energietechnik GmbH http://www.trnsys.de

CSTB – Centre Scientifique et Technique du Bâtiment http://software.cstb.fr

TESS – Thermal Energy Systems Specialists http://www.tess-inc.com

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About This Manual

The information presented in this manual is intended to provide a simple guide to get you started using TRNSYS 17. This manual is not intended to provide detailed reference information about the TRNSYS simulation software and its utility programs. More details can be found in other parts of the TRNSYS documentation set. The latest version of this manual is always available for registered users on the TRNSYS website (see here below).

Revision history

• 2004-09 For TRNSYS 16.00.0000 • 2005-02 For TRNSYS 16.00.0037 • 2006-01 For TRNSYS 16.01.0000 • 2006-06 For TRNSYS 16.01.0002 • 2007-03 For TRNSYS 16.01.0003 • 2009-11 For TRNSYS 17.00.0006 • 2010-04 For TRNSYS 17.00.0013

Where to find more information

Further information about the program and its availability can be obtained from the TRNSYS website or from the TRNSYS coordinator at the Solar Energy Lab:

TRNSYS Coordinator

Thermal Energy System Specialists, LLC 22 North Carroll Street – suite 370 Madison, WI 53703 – U.S.A.

Email: [email protected] Phone: +1 (608) 274 2577

Fax: +1 (608) 278 1475

TRNSYS website: http://sel.me.wisc.edu/trnsys

Notice

This report was prepared as an account of work partially sponsored by the United States Government. Neither the United States or the United States Department of Energy, nor any of their employees, nor any of their contractors, subcontractors, or employees, including but not limited to the University of Wisconsin Solar Energy Laboratory, makes any warranty, expressed or implied, or assumes any liability or responsibility for the accuracy, completeness or usefulness of any information, apparatus, product or process disclosed, or represents that its use would not infringe privately owned rights.

The software described in this document is furnished under a license agreement. This manual and the software may be used or copied only under the terms of the license agreement. Except as permitted by any such license, no part of this manual may be copied or reproduced in any form or by any means without prior written consent from the Solar Energy Laboratory, University of Wisconsin-Madison.

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TRNSYS Contributors

S.A. Klein W.A. Beckman J.W. Mitchell

J.A. Duffie N.A. Duffie T.L. Freeman

J.C. Mitchell J.E. Braun B.L. Evans

J.P. Kummer R.E. Urban A. Fiksel

J.W. Thornton N.J. Blair P.M. Williams

D.E. Bradley T.P. McDowell M. Kummert

D.A. Arias M.J. Duffy

Additional contributors who developed components that have been included in the Standard Library are listed in Volume 4.

Contributors to the building model (Type 56) and its interface (TRNBuild) are listed in Volume 5.

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T

ABLE OF CONTENTS

1. GETTING STARTED 1–8

1.1. What is TRNSYS? 1–8

1.2. The TRNSYS Suite 1–10

1.2.1. The TRNSYS Simulation Studio 1–10

1.2.2. The TRNSYS Simulation Engine 1–11

1.2.3. The Building Visual Interface 1–12

1.2.4. TRNEdit and TRNSED Applications 1–12

1.2.5. TRNSYS Add-ons 1–13

1.3. Installation 1–14

1.3.1. System requirements 1–14

1.3.2. Installing TRNSYS 17 1–15

1.3.3. Registering TRNSYS 1–16

1.3.4. Installing the expanded weather data 1–17

1.4. Using TRNSYS examples 1–18

1.4.1. Opening and running a simple example 1–18

1.4.2. Opening and running an example with the Multizone building model (Type 56) 1–25

1.5. Creating a TRNSYS project 1–30

1.5.1. System description 1–30

1.5.2. Modeling approach 1–31

1.5.3. Step-by-Step instructions to create the Project 1–32

1.6. Creating a building project 1–40

1.6.1. Using the Building wizard 1–40

1.6.2. Using the 3D Building Project 1–46

1.6.3. Modifying the wizard-generated project 1–47

1.7. Using TRNEdit and creating a distributable (TRNSED) application 1–52

1.7.1. Starting point: TRNSYS Studio project 1–52

1.7.2. Editing the TRNSED file in TRNEdit 1–54

1.7.3. Some refinements 1–57

1.7.4. Adding pictures, links and multiple tabs 1–61

1.7.5. Creating the redistributable application 1–63

1.8. Creating a new component 1–65

1.8.1. Create the component proforma 1–65

1.8.2. Generating a Fortran code skeleton and a compiler project 1–66 1.8.3. Using other compilers or creating Types in other programming languages 1–72

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1.9.1. Running TRNSYS in batch mode 1–73

1.9.2. Running TRNSYS in Hidden mode 1–73

1.10. More TRNSYS Examples 1–75

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1. G

ETTING

S

TARTED

The getting started manual explains what TRNSYS is and what programs make the TRNSYS suite. You will learn how to install TRNSYS, how to open and run the examples, how to create a project in the Simulation Studio and how to use the Multizone Building interface (TRNBuild).

1.1. What is TRNSYS?

TRNSYS is a complete and extensible simulation environment for the transient simulation of systems, including multi-zone buildings. It is used by engineers and researchers around the world to validate new energy concepts, from simple domestic hot water systems to the design and simulation of buildings and their equipment, including control strategies, occupant behavior, alternative energy systems (wind, solar, photovoltaic, hydrogen systems), etc.

One of the key factors in TRNSYS’ success over the last 35 years is its open, modular structure. The source code of the kernel as well as the component models is delivered to the end users. This simplifies extending existing models to make them fit the user’s specific needs.

The DLL-based architecture allows users and third-party developers to easily add custom component models, using all common programming languages (C, C++, PASCAL, FORTRAN, etc.). In addition, TRNSYS can be easily connected to many other applications, for pre- or post-processing or through interactive calls during the simulation (e.g. Microsoft Excel, Matlab, COMIS, etc.). TRNSYS applications include:

• Solar systems (solar thermal and PV)

• Low energy buildings and HVAC systems with advanced design features (natural ventilation, slab heating/cooling, double façade, etc.)

• Renewable energy systems • Cogeneration, fuel cells

• Anything that requires dynamic simulation! Some TRNSYS jargon:

A TRNSYS project is typically setup by connecting components graphically in the

Simulation Studio. Each Type of component is described by a mathematical

model in the TRNSYS simulation engine and has a set of matching Proforma's in the Simulation Studio The proforma has a black-box description of a

component: inputs, outputs, parameters, etc.

TRNSYS components are often referred to as Types (e.g. Type 1 is the solar

collector). The Multizone building model is known as Type 56.

The Simulation Studio generates a text input file for the TRNSYS simulation engine. That input file is referred to as the deck file.

In this manual, %TRNSYS17% refers to the TRNSYS 17 installation directory, i.e. C:\Program Files\Trnsys17 if you chose to keep the default location

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1.2. The TRNSYS Suite

TRNSYS consists of a suite of programs: The TRNSYS Simulation Studio, the simulation engine (TRNDll.dll) and its executable (TRNExe.exe), the Building input data visual interface (TRNBuild.exe), and the Editor used to create stand-alone redistributable programs known as TRNSED applications (TRNEdit.exe).

1.2.1. The TRNSYS Simulation Studio

The main visual interface is the TRNSYS Simulation Studio. From there, you can create projects by drag-and-dropping components to the workspace, connecting them together and setting the global simulation parameters.

The Simulation Studio saves the project information in a Trnsys Project File (*.tpf). When you run a simulation, the Studio also creates a TRNSYS input file (text file that contains all the information on the simulation but no graphical information).

Figure 1-1: The TRNSYS Simulation Studio

The simulation Studio also includes an output manager from where you control which variables are integrated, printed and/or plotted, and a log/error manager that allows you to study in detail what happened during a simulation.

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You can also perform many additional tasks from the Simulation Studio: Generate projects using the "New Project Wizard", generate a skeleton for new components using the Fortran Wizard, view and edit the components proformas (a proforma is the input/output/parameters description of a component), view output files, etc.

1.2.2. The TRNSYS Simulation Engine

The simulation engine is programmed in Fortran and the source is distributed (see the \SourceCode directory). The engine is compiled into a Windows Dynamic Link Library (DLL), TRNDll. The TRNSYS kernel reads all the information on the simulation (which components are used and how they are connected) in the TRNSYS input file, known as the deck file (*.dck). It also opens additional input files (e.g. weather data) and creates output files.

The simulation engine is called by an executable program, TRNExe.exe, which also implements the online plotter, a very useful tool that allows you to view dozens of output variables during a simulation.

Figure 1-2: The online plotter in TRNExe

The online plotter provides some advanced features such as zooming and display of numerical values of the variables at any time step, as shown in the zoom part of Figure 1-2.

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1.2.3. The Building Visual Interface

TRNBuild is the tool used to enter input data for multizone buildings. It allows you to specify all the building structure details, as well as everything that is needed to simulate the thermal behavior of the building, such as windows optical properties, heating and cooling schedules, etc.

Figure 1-3: TRNBuild

TRNBuild creates a building description file (*.bui) that includes all the information required to simulate the building. Note that this was not the case in TRNSYS 15 and earlier where the window library (w4-lib.dat) was always required to run a simulation.

1.2.4. TRNEdit and TRNSED Applications

TRNEdit is an specialized editor that can be used to create or modify TRNSYS input files (decks). This is not recommended in general and only advanced users should attempt to modify deck files by hand. Most users should rely on the Simulation Studio to generate and modify deck files. On the other hand, TRNEdit can be used to create redistributable applications (known as TRNSED applications). Those executables can be freely distributed to end-users who do not have a TRNSYS license in order to offer them a simplified simulation tool. The distributable includes a dedicated visual interface designed by adding special commands to the TRNSYS input file.

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Figure 1-4: TRNEdit – Tabbed view to design TRNSED applications

For more information on TRNSED applications licensing, please check the license.txt file in your installation.

1.2.5. TRNSYS Add-ons

TRNSYS offers a broad variety of standard components, and many additional libraries are available to expand its capabilities:

• TRNLIB: sel.me.wisc.edu/trnsys/trnlib (free component library) • STEC library: sel.me.wisc.edu/trnsys/trnlib/stec/stec.htm • TRANSSOLAR libraries: www.trnsys.de

• Trnsys3d (Plugin for Google™ Sketchup): www.trnsys.de • TESS libraries: www.trnsys.com

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1.3. Installation

1.3.1. System requirements

1.3.1.1. Software

OPERATING SYSTEM

TRNSYS requires Windows 2000, ME, Windows XP, or Vista. Windows XP is recommended due to known issues in resource management in previous Windows versions (those issues are not related to TRNSYS nor its utility programs).

COMPILERS

Thanks to the drop-in DLL technology, no compiler is required to add components to TRNSYS if you obtain them as a precompiled DLL.

If you wish to debug TRNSYS or to add components for which you received the Fortran code, you will need a Fortran compiler (Please see the Programmer's Guide for supported compilers). If you wish to create your own components, you will need a compiler capable of creating a DLL. This includes any recent Windows-compatible compiler for C++, Delphi, Fortran or other languages. OTHER

Viewing the documentation requires the free Acrobat reader (Version 6.0 or higher is recommended to benefit from advanced searching capabilities).

1.3.1.2. Hardware

TRNSYS requirements will mostly depend on the simulations you want to run. The specifications here below list the basic requirements and the recommended configuration. The latter should allow you to run yearly simulations with a 0.1 sec time step using the full capabilities of the online plotter, while the basic configuration will allow you to run more typical simulations.

MINIMUM CONFIGURATION

• Pentium III processor or equivalent • 128 MB of RAM

• 200 MB of available disk space (up to 2 GB if you install all the optional weather data files)

RECOMMENDED CONFIGURATION

• Pentium IV processor 2.0 GHz or equivalent • 512 MB of RAM

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1.3.2. Installing TRNSYS 17

Run the Setup program (trnsys17-setup-17-xx-xxxx.exe), where xx.xxxx is the exact release number. The Setup program will guide you through a series of dialog boxes with simple options. You will be prompted to accept the license agreement to continue the installation.

Figure 1-5: Installing TRNSYS 17 - Part 1

You can navigate between the dialog boxes using the Back and Next Buttons. You will go through a few basic options.

Figure 1-6: Installing TRNSYS 17 - Part 2

You will be asked to choose a default set of libraries for building data (materials and glazing). If you have many TRNSYS 16 projects that you need to update, choose the libraries that you were using in TRNSYS 16. If your country is listed, use those libraries (they were created by local distributors and are often in languages other than English). If you do not know what to do, keep the default choice (Basic). Note that you can always change the default libraries later in TRNBuild. You will then be asked if you want to create shortcuts and associate file extensions with TRNSYS. You should select that option unless you have already installed TRNSYS 17 and you have customized your shortcuts or associations.

When you have selected a few options such as the destination directory, Setup will ask your confirmation to start the installation.

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Figure 1-7: Installing TRNSYS 17 – Part 3

When the installation is complete, the Setup program will attempt to copy your user registration data (the "user17.id" file) to the destination folder. If you install from a CD provided by your distributor, Setup should be able to locate the file. If it is not the case (e.g. if you are installing a downloaded version), you should copy the "user17.id" file provided by you distributor according to the message displayed on the last screen of the Setup program.

When you click "Finish", Setup will exit and launch your default browser to display the release notes of the version you have just installed. You can skip this by unchecking the "Display Release Notes" checkbox on the last screen of the Setup program (this is not recommended as the Release Notes have important information on the program you have just installed).

1.3.3. Registering TRNSYS

One new feature of TRNSYS 17 is that you must now register your copy of TRNSYS online. The procedure is as follows.

• Launch the Simulation Studio by using the created shortcut or by browsing to %TRNSYS17%\Studio\Exe and launching the Program called Studio.exe.

• The first time you launch the Studio, a window will pop up containing a code that corresponds to the processor of your computer and a link to a website.

• Click the link and you will arrive at the following website:

http://sel.me.wisc.edu/trnsys/trnsys17registration.html

• The website contains links to each of the TRNSYS Distributors. Click on the “Register your TRNSYS 17” link listed underneath the Distributor from whom you purchased TRNSYS 17; you will be redirected to a second webpage.

• Once you are redirected, you are asked to enter two pieces of information, the email address that you gave when you purchased TRNSYS 17 and paste the access code that the Simulation Studio displayed. Enter the requested information into the appropriate fields and click “okay” or “get the activation key”

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• The website will return back an activation key code. Copy this code and paste it back in the original window in the Simulation Studio. Now you are registered!

If you have trouble with the registration, make sure that you are using the same email address that you gave when you purchased TRNSYS. The website is checking a data base to make sure that the email address that you are entering is associated with a copy of TRNSYS.

1.3.4. Installing the expanded weather data

After installing TRNSYS 17, the setup program will try to copy your user registration data to the destination directory. The registration information is contained in a small text file, user17.id. If you install from a CD obtained from your distributor, Setup should find the user17.id file and install it. If you downloaded TRNSYS from the web, Setup will inform you in case it can't find the user17.id file. In that case you just need to copy that file to the installation directory (C:\Program Files\Trnsys17 by default). Please contact your distributor if you cannot locate your registration information.

The TRNSYS Setup installs a few weather data files that will show you an example of the available data sources and data formats. However, TRNSYS 17 comes with a comprehensive set of weather data files including more than 1000 locations in more than 140 countries. Please refer to Volume 8 of the documentation (Weather Data) for more information on the available data sources and locations.

If you wish to proceed with the installation of the expanded weather data base, just run the weather data Setup program, trnsys17-weather-17-xx.exe (where xx is the release number). The Setup program is very similar to the TRNSYS 17 installation program and will lead you through a few steps with dialog boxes.

Figure 1-8: Installing the expanded weather data

You can choose which datasets to install or not (the available packages may not match the screenshot here below depending on your version). Please note that installing all the data files will require more than 1.5 GB of available disk space on your computer.

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1.4. Using TRNSYS examples

This section explains how you can quickly get started using TRNSYS by opening and running the examples provided with the distribution. You can then start creating your own projects by making changes to those examples.

1.4.1. Opening and running a simple example

Launch the simulation Studio by using the created shortcut or by browsing to %TRNSYS17%\Studio\Exe and launching the Program called Studio.exe

Go to File/Open and select %TRNSYS17%\Examples\Begin\Begin.tpf. A TRNSYS project consists of components (e.g. a solar collector, a data reader, a printer) linked together.

Figure 1-9: The "Begin" example

Note: Each component is assigned two numbers: a Type and Unit numbers. If you press the key F2 you will see these two values for all of the components present in the simulation.

1.4.1.1. Component configuration

You can check a component's configuration by double-clicking its icon. This will open a window with multiple tabs. When you open the window, the foremost tab shows a list of parameters and

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their value (the solar collector parameters are shown in Figure 1-9). You can see additional information about the parameters by clicking the "More" button.

You can explore the different tabs to view the component's inputs, outputs and derivatives (if any – derivatives are capacitive variables of the component, e.g. nodes representing a given amount of water in a storage tank).

Note: The values and units displayed in the input tab give the initial values for the corresponding inputs. They are overridden during the simulation if those inputs are connected to other components

1.4.1.2. Connections

If you double-click on a link between two components, you will open a new window that lists all input-output connections inside that link. Figure 1-10 shows the link between Type 15 (weather data reading and processing) and Type 1b (solar collector)

Figure 1-10: Example of connection window

If there are many available inputs and outputs, the lists will be longer than what can be displayed. You can resize the window and/or use the scrollbars.

Note: The Simulation Studio can be set to auto-scroll in the connection window (as well as in the project window). If you want to enable/disable that mode, go to File/Settings/Project and check/uncheck the "auto-scroll" boxes.

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It may be easier to make new connections after aligning a given output with the input to which it is connected. To do this, click on the bottommost icon on the left (see Figure 1-11 for an example).

Figure 1-11: Aligned connection window

You can also decide to show only the inputs and outputs that have given dimensions. Figure 1-12 shows the results when "angle" is selected. Note that inputs/outputs with "any" or "unknown" dimensions will always be displayed.

Figure 1-12: Filtered connection window

Alternatively, you can use the table view to display and manage connections: Just switch from the "Classic" tab to the "Table" tab. The result is shown in Figure 1-13.

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Figure 1-13: Connections window – Table tab

1.4.1.3. Running the simulation and viewing the results

You can run a simulation by pressing the "F8" key, which is the shortcut for "Calculate/Run Simulation".

THE ONLINE PLOTTER

If at least one "online plotter" component is present in the simulation, an online plot will be displayed during the simulation. The online plotter offers several features that will help you analyze the simulation results while it is running and after it is done.

You can interrupt / resume the simulation while it is running by right-clicking anywhere in the plot, by using the "F7" and "F8" keys, or using the "Calculation/Stop" and "Calculation/Resume" menu entries. The "Pause at…" command is also very useful when you want to diagnose some problems occurring at a given time in a simulation.

When the simulation is stopped, you can use the "Plot options" menu to change the plot background from black to white, or increase the line thickness. You can also change the left and right Y-axis limits by clicking on the axes themselves, which will display a dialog box (see Figure 1-14). Please note that changes to those limits will be lost if you re-run the simulation. You should change the online plotter parameters in the simulation itself (double-click on the online plotter icon) if you want changes to be permanent.

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Figure 1-14: Online plotter in a paused simulation with Y-axis control box

You can hide or show any variable in the plot by clicking on its name in the legend fields. For example clicking in the red circle in Figure 1-14 would hide/show the QAux plot.

ANALYZING THE SIMULATION: ZOOMING AND DISPLAYING NUMERICAL VALUES

You can zoom on part of the plot to have a more detailed view of a shorter time interval. Just click on the upper-left corner of the area you want to zoom in and drag the mouse pointer to the lower-right corner, then release the mouse button. In the zoom window, you can adjust the Y-axis limits

but also the X-axis (time) limits by clicking on the axes. This is very useful when you want to

study such a short period of time that it is hard to zoom on that period right away.

You can display the numerical value of any variable at any point in time in both the "normal" and the "zoom" windows. Press the SHIFT key and mover the mouse over the graph. The variable labels will be replaced with their value (and "time" will be replaced with the simulation time). This is shown in Figure 1-15 for the zoom window.

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Figure 1-15: Online Plotter: Displaying numerical values

Note: By pressing SHIFT and moving the mouse over the plot, you will display the values plotted by the online plotter, which are interpolated between TRNSYS time steps. If you want to see only the actual simulation time steps, pres CTRL-SHIFT when moving the mouse. This can be useful to study control signal switching from 0 to 1, for example, since the online plotter will draw a continuous line between those 2 states and it will show interpolated values that do not correspond to any simulated values.

A feature new to TRNSYS 17 gives you the ability to plot the contents of two online plots on the same screen. If you have defined more than one Type65 Online Plotter in your simulation, select “Create Double Online” from the “Plot Options” menu. Select the names of the two plots that you want to display from the two pull-down menus and give your Double Online a name in the “Tab Caption” field. Click OK and you’ll notice that you now have one more Online Plot tab at the bottom of your plot screen; this one displays the contents of both individual online plots. You may notice that one of the two plots is outlined in bold. By holding down the SHIFT key, and you are able to move the mouse over the plot and display variable values. However, only the values of the plot that is outlined in bold will be displayed (due to space restrictions).

CLOSING THE ONLINE PLOTTER AND ANALYZING PRINTED RESULTS

At the end of the simulation, you will be asked if you wish to exit the online plotter. If you click "No", you will be able to use the online plotter commands described here above. If you click "Yes", you will come back to the Simulation Studio, from where you can view the printed results. You can open external files (input or output files) by using the "Calculate/Open/External Files" menu or by double-clicking on the component that uses a file, switching to the "External Files" tab and using the "Edit" button (Figure 1-16). Both actions will open the file using the editor set in "File/Settings/Directories/Text Editor" (Notepad by default).

Note: In a file name, "***" means that TRNSYS will use the input file (.dck) filename to assign a name at the file at runtime. Example: if your project's input file is called "MyProject.dck" and you type in "***.dat" as the output file name, TRNSYS will create a file called "MyProject.dat".

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Warning: the input (deck) file name is not always the same as the TRNSYS Studio project's name. The deck filename is set in the project's Control Cards, which can be accessed by "Assembly/Control Cards" or by the appropriate toolbar button

Figure 1-16: Opening external files

The Standard TRNSYS components always create text files, but you can use any file extension in a project. In particular, some users find it convenient to use the file extension registered with their preferred spreadsheet program, e.g. ".xls" for Microsoft Excel. This allows opening those files in the spreadsheet program by double-clicking their name in Windows Explorer. Please note, however, that the created files only have plain text information. Special features, like colors, cannot be created with the standard components.

TROUBLESHOOTING A SIMULATION (THE ERROR MANAGER)

During a simulation, TRNSYS writes messages to a special file called the Log file. That file has the same name as the input file (deck) with a ".log" extension. Another file, the Listing file, is also created (the listing file also has all messages but in addition it repeats the input file and has some additional printed outputs like the results of a "Trace" command, which prints the inputs and outputs of a component at each iteration).

The Simulation Studio provides access to the Log and Listing file through the Error Manager, which can be accessed by clicking on the LST button. Figure 1-17 shows an example of error message when an equation refers to a non-existent variable. The TRNSYS simulation ends with

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a "TRNSYS Errors" dialog box. You can then return to the Simulation Studio by clicking OK, and you can launch the Error Manager to analyze notices, warnings and error messages that were generated during the simulation.

Figure 1-17: The Error Manager

The "Units stats" and "Types stats" of the Error Manager present additional information on the calculation time spent in each component and on the number of times each component was called. Finally, clicking on the "Lst File" tab will open the listing file in a text editor.

1.4.2. Opening and running an example with the

Multizone building model (Type 56)

The "Sunspace" example is a simple example inspired by BESTEST Case 960. BESTEST (Building Energy Simulation programs TEST) is the methodology developed in the framework of the IEA to test and diagnose the simulation capabilities of the exterior envelope portions of building energy simulation programs.

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1.4.2.1. Opening and running the example

In the simulation Studio, open %TRNSYS17\Examples\SunSpace\SunSpace.tpf. You can explore the connections and the components configuration as explained here above.

Figure 1-18: The SunSpace example

When you run the example (F8), TRNSYS launches TRNBuild in order to process the building input data. This ensures that the data used in TRNSYS matches the latest version of the .bui file and that Type 56 will find all intermediate files it uses for the simulation (.bld, .trn and .inf). After the automatic call to TRNBuild, the online plotter is displayed and the simulation runs.

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Figure 1-19: SunSpace example: online plotter with zoom on air and operative temperatures Figure 1-19 shows the online plotter with a zoom window displaying the air and operative temperatures on February 1st.

1.4.2.2. Editing the building description

A building model involves too many parameters to use a standard proforma in the Simulation Studio. The building model is described in a special file, the .bui file. You can edit the building description by right-clicking on the building icon and selecting "Edit Building", as shown in Figure 1-20. This will launch TRNBuild and open the corresponding .bui file.

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Figure 1-20: SunSpace example: Launching the Building Editor, TRNBuild

You can explore the building parameters from the top level (thermal zones) to the bottom level (thermal properties of one layer in a massive wall). You can, for example, change the window area in the zone "SunZone" from 12 to 1, as illustrated in Figure 1-21. To do this, click on the name of the zone (SUNZONE) in the TRNBuild Manager, then in the zone window select the 3rd wall (BST_H_EXT wall Type with orientation SOUTH). The properties of windows pertaining to that wall will be displayed in the right column.

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Figure 1-21: SunSpace example: changing the window area

After changing the area, you will notice a significant decrease in summer temperatures compared to Figure 1-19.

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1.5. Creating a TRNSYS project

In this section, we will build the "Begin" example from scratch, starting from a physical description of the system that has to be modeled.

1.5.1. System description

The simulated system is represented in Figure 1-22. It is a simple solar thermal application where solar collectors are used to preheat water in an industrial process.

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Figure 1-22: A simple solar pre-heating application

The water is pumped from 8 am to 6 pm every day with a pump that has a maximum flow rate of 50 liters per hour. The supply water enters the pump at a constant temperature of 20°C. The pump electrical power is 16.7 W and it is assumed that 5% of the electrical power, converted to heat, is transferred to the fluid.

The solar array consists of two 1-m² collectors connected in parallel. 1 m² is the aperture area (glazing area for a flat-plate collector), which is consistent with the efficiency parameters given here below. Both collectors are identical. Their performance has been tested with a flow rate of 40 l/h-m² and the efficiency parameters were found to be η0 = 0.8, a1 = 3.61 W m-2 K-1, a2 = 0.014

W m-2 K-2, with:

(

)

⎟⎟

⎠

⎞

⎜⎜

⎝

⎛

=

−

=

G

A

Q

G

T

a

G

T

a

a a i a i

η

&

η

2 2 1 0 , where

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η Collector efficiency [-]

η0 Intercept (maximum) efficiency [-]

a1 First order loss coefficient [W m-2 K-1]

a2 Second order loss coefficient [W m-2 K-2]

G Solar radiation in the collector plane [W m-2_]

Ti Fluid inlet temperature [°C]

Ta Ambient air temperature [°C]

Q& Useful Heat Transfer Rate of the collector [W]

Aa Aperture area of the collector [m²]

Furthermore, the zero and first order incident angle modifiers according to ASHRAE testing method were found to be b0 = 0.2 and b1 = 0.0. The solar collectors have a slope of 45° and face due South (note: this is not intended to provide an example of optimal solar collector orientation for the given location).

In Europe, solar collector test reports often give the efficiency in a slightly different way from here above: The average (or mean plate) temperature is used instead of the inlet temperature. Make sure to take this into account in the efficiency mode (Parameter 4) of Type 1 if this is the case (that parameter should then be set to 2)

The auxiliary heater has a maximum power of 1400 W and losses should not be taken into account. The set point is 60°C.

The system is located in Ouagadougou, Burkina Faso. Expected results from the simulation are a hourly plot of system temperatures and heat transfer rates, as well as printed values of the integrated energy transfers Qaux and Qcoll (auxiliary energy rate and useful solar energy rate). The period of interest is January and February.

1.5.2. Modeling approach

Before starting creating the project in the Simulation Studio, we need to study the simulated system, decide what factors will be of interest and identify the components that will be used in the simulation.

The solar system consists of solar collectors, a pump, and an auxiliary heater. We also need to read and process weather data for Ouagadougou and output some results (both to the online plotter and to a printed file).

The following components will be used:

• Type 15 Weather data reader and processor: This component reads weather data and processes it to calculate the solar radiation properties on any surface.

• Type 3 Pump: Simple pump model (imposed flow rate)

• Type 1 Solar collector: adapted to flat-plate collectors with quadratic efficiency parameters. • Type 24 Integrator: will be used to integrate energy rates

• Type 25: Printer • Type 65: Online plotter

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1.5.3. Step-by-Step instructions to create the Project

1.5.3.1. Creating an empty project

In the Simulation Studio, go to File/New and select Empty Project, then click on "Create". By default the project is created in %TRNSYS17%\MyProjects in a new folder that is named Projectn where n is a number (it is omitted for the first project created, which is just called Project.tpf). NOTE: if the Simulation Studio does not launch but instead displays a window asking you to register TRNSYS, please refer to section 1.3.3 for instructions.

This will create an empty project. You can first set some global simulation parameters by going to "Assembly / Control Cards" or by clicking on the document icon as shown in Figure 1-23. You just need to change the simulation stop time so it displays 1416 (end of February) instead of the default value. If you scroll down in the Control Cards window, you will notice that the deck file is automatically given the same name as the project file with a .dck extension. You can change it if you wish.

1.5.3.2. Adding components and configuring them

You can now start adding components to the simulation.

WEATHER DATA READING AND PROCESSING

We will start with the data reader and solar radiation processor, Type 15. You can find it in the Direct Access Tool (tree structure in a docked window at the right of the screen). Type 15 is under "Weather Data Reading and Processing". We need to read weather data for Ouagadougou (Burkina Faso, Africa), which is available as part of the weather database generated with Meteonorm (refer to Volume 8 of the documentation for more details on Weather Data). Meteonorm files use the TMY2 data format, so we will select the proforma for Type 15 that is in \Standard Format\TMY2. You can add the component to the project by dragging its icon from the direct access tool to the project window (see Figure 1-23).

Component configuration

• Once it is displayed in the project window, if you double-click on the component, you will have access to its parameters, inputs, outputs and other configuration settings like the external files. In our case we want to switch to the "External Files" tab and select the file for Ouagadougou, which is %TRNSYS17%\Weather\Meteonorm\Africa\BF-Ouagadougou-655030.tm2.

• Type 15 is also used to calculate the incident radiation on the solar collectors' plane so we need to set the slope and azimuth of the tilted surface appropriately. In the "Parameters" tab, set the “Slope of the surface” to 45 and the azimuth to 0 (0 means facing the equator, i.e. South in the Northern hemisphere).

The “-2” in Type15-2 is an indication that this particular component has a number of different modes of operation. In the case of Type15, we have chosen the mode of operation that tells the component to read a weather file whose syntax follows the Typical Meterorological Year version 2 format. You will notice other components that have a letter designator following the Type number (Type3a and Type3b for example). Again, both proformas refer to the same model but to different modes of its operation.

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Figure 1-23: Control cards and Type 15 (Weather data reader / processor) SOLAR SYSTEM

We will now add the 3 components required for the physical system model: Pump, Solar collector and Auxiliary heater. The selected components are:

• Hydronics\Pump\Single speed\Type3b

• Changes to default configuration: set maximum flow rate (Parameter 1) to 50 kg/h • HVAC\Auxiliary Heaters\Type6

• Changes to default configuration: set maximum power (Parameter 1) to 5040 kJ/h = 1400 W

• Solar Thermal Collectors\Quadratic Efficiency Collector\2nd-Order Incidence Angle Modifiers\Type1b

• Changes to default configuration: set the collector area (Parameter 2) to 2 m². Note that the given area is the total collector area, not the area of each module

• No other changes are required if we accept some rounding errors on the efficiency parameters (the exact values in kJ/h are 12.996 kJ/h-m²-K and 0.0504 kJ/h-m²-K²). You do not need to change the initial value of the collector slope (Input 9) because it will be connected to the output of Type 15 (This will make it easier to change the collector slope later since only one value will need to be changed).

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UTILITY COMPONENTS

We need to impose the flow rate on the pump by sending a time-varying control signal and we also need to integrate, plot and print the results. We will add 4 components:

• Utility\Forcing Functions\General\Type14h

• Parameters: the profile we want to define is a step-like function that is 0 from 0 to 08:00, 1 from 08:00 to 18:00, and 0 again from 18:00 to 24:00 (the profile is repeated after 24h). I order to create that profile, we will need 6 points: (0;0), (8;0), (8;1), (18;1), (18;0), (24;0). So we should declare that we need 5 points besides the initial one, and enter the value of parameters as follows: 0; 0; 8; 0; 8; 1; 18; 1; 18; 0; 24; 0.

The Simulation Studio offers a convenient way to define a forcing function using a graphical plug-in for Type 14. Please refer to section 1.5.3.6 for details.

For step-like forcing functions, it is recommended to define the profile by repeating the time values with two different function values, as it is done here above, and to use the "average value of function" output of Type 14. This will ensure consistent results for any chosen time step

• Output\Online Plotter\Online Plotter Without File\Type65d

• Parameters: we will plot 3 variables on the left-axis, 2 on the right-axis. By setting the axis limits to [-100; 100] for the left (temperatures) and [0; 10000] for the right (heat transfer rates) we will ensure minimum overlapping of the plots.

• Output\Printegrator\User-Defined Period\Type46a

• Without any changes to the default configuration, the printegrator (combined integrator and printer) will output results from the simulation start to the simulation end to a file named ***.out where *** is the deck file name (Projectn if you did not rename it). You should change the number of printed outputs to 2 (answer to the question: " How many variables are to be printed by this component?" in the Input tab).

Although it is convenient for the purposes of this example, it is NOT recommended that you drag all of the components for a given simulation out into the project workspace before linking any of them together. A much more error-proof method of developing a simulation is to drag out a single component, set its parameters and input initial values, connect it to the existing components of the simulation in a meaningful way and then run the simulation, plotting a few output variables in an online plotter. Make sure that you understand the results as you go and you will spend far less time debugging your simulation later on.

1.5.3.3. Connecting components

Components are connected using the Link tool, which is activated by pressing the link button (see Figure 1-24). When you move the mouse over a component icon, the 8 available connection points become visible. Click one of them to select the starting point, then go to the component you want to link and select a connection point again. Click to create the link. The newly created link is empty, i.e. it does not connect any (output; input) couple yet. This is shown by a different link color (blue by default, while links with connections are black).

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Figure 1-24: Connecting two components with the link tool

To connect outputs to inputs inside a link, you must go back to the selection tool by clicking on the white arrow icon or by pressing the ESC key. You can then double-click on the link and edit the connections as shown in Figure 1-24. You can use the filter and align tools and the alternative "table view" to make connections easier, as discussed in section 1.4.1.2.

The connections to be made in our case are listed here below:

SYSTEM CONNECTIONS

Type15 (Weather data) to Type1 (Solar collector)

• Dry bulb temperature → Ambient temperature • Total horizontal radiation → Total horizontal radiation

• Sky diffuse radiation on the horizontal → Horizontal diffuse radiation • Total tilted surface radiation for surface → Incident radiation

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• Slope of surface → Collector slope • Ground reflectance → Ground reflectance

Type 14 (Forcing Function) to Type 3 (Pump)

• Average value of function → Control signal

Type 3 (Pump) to Type 1 (Solar collector)

• Outlet fluid temperature → Inlet temperature • Outlet flow rate → Inlet flow rate

Type 1 (Solar Collector) to Type 6 (Auxiliary heater)

• Outlet temperature → Inlet fluid temperature • Outlet flow rate → Inlet flow rate

CONNECTIONS TO OUTPUT DEVICES

Connections to Type 46 (Printegrator)

• Type 1 (Solar collector), Useful energy gain → Input to be integrated & printed -1 • Type 6 (Auxiliary heater), Required heating rate → Input to be integrated & printed -2

Connections to Type 65 (Online plotter)

• Type 3 (Pump), Outlet fluid temperature → Left axis variable-1 • Type 1 (Solar collector), Outlet temperature → Left axis variable-2 • Type 1 (Solar collector), Useful energy gain → Right axis variable-1 • Type 6 (Auxiliary heater), Outlet fluid temperature → Left axis variable-3 • Type 6 (Auxiliary heater), Required heating rate → Right axis variable-2

Anytime during the process of adding components, if you press F2, the Studio will display the Type number and the Unit number. This option is very useful when you want to know this information about each component.

1.5.3.4. Setting labels

Some output components allow defining labels, or descriptors, for outputted variables. In the Simulation Studio, those variable descriptors are set in the input tab, instead of the initial value of inputs.

In our case, we need to define descriptors for Type 46 (Printegrator) and Type 65 (Online plotter). Figure 1-25 shows possible names for the printed and plotted variables.

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Figure 1-25: Defining variable descriptors for output components

1.5.3.5. Running the project and analyzing the results

Go to Calculate / Run Simulation or press F8 to run the simulation. The online plotter will display simulation results during the simulation and output files will be generated. If there is an error while processing the input file or running the simulation, you can view detailed error messages using the Error Manager (see "Troubleshooting a simulation" in section 1.4.1.3).

1.5.3.6. Some alternative options offered by the Studio

CONFIGURING TYPE14(FORCING FUNCTION) USING ITS GRAPHICAL PLUG-IN

Type 14 is one of the standard components for which the plug-in technology has been implemented. In the Simulation Studio, any component can be associated with a separate executable program to help users setup its configuration. In the case of Type 14, the plug-in offers a graphical way of defining the time profile of the forcing function.

You can launch the plug-in by clicking on the wizard icon in the component's proforma. This will launch the external program, as shown in Figure 1-26. You can define the desired profile using the plug-in. When you are done, click OK and the plug-in will transfer the parameters to Type 14 and close.

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Figure 1-26: Control Using the Type 14 (Forcing Function) Plug-in

DEFINING PLOTTED AND PRINTED VARIABLES USING THE OUTPUT MANAGER

In the step-by-step instructions here above, we have added an online plotter and a printer to the simulation, as we added other components. The Simulation Studio offers another way to plot and print variables: the Output Manager.

The Output Manager is launched using the "Assembly" Menu. Figure 1-27 shows how an online plotter with the same connections as the ones described here above can be defined:

• Add an online plotter (online plotter icon on the right)

• Click on the created online plotter in the tree structure on the right and configure it to have 3 left-axis variables and 2 right-axis variables. You can also change axis limits, etc. here. • Expand the online plotter tree on the right and the desired component (e.g. pump) tree on

the left, select the output to be connected to the first plotted variable (outlet fluid temperature), select the "left-axis variable–1" of the online plotter, and click on the right arrow to make the connection. Repeat for all other variables to be plotted.

When you are done, close the output manager. A new online plotter named "System_Plotter" has been created in the project. You can modify the plotter parameters and connections indifferently in the project window or in the output manager. In particular, you can change the variable label ("name") in the "input" tab of the proforma.

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Figure 1-27: The output manager

For output files, there is even a shorter way to send outputs to a new printer: for any component, double-click on its icon and go to the "output" tab. Next to each output is a checkbox. If you check one variable, it will be automatically sent to a system printer, which is created the first time an output is selected. This is illustrated in Figure 1-28 for a solar collector (the first output would be sent to the default printer). You can then go to the output manager or to the System Printer icon to change some parameters like the start and stop time for printing, the filename, etc.

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1.6. Creating a building project

This section presents step-by-step instructions to create a simple building project using the TRNSYS Studio Building Wizard. For detailed instructions on how to input building data using TRNBuild, please refer to Volume 5 of the documentation.

1.6.1. Using the Building wizard

The building wizard is described in detail in Volume 2 (Using the Simulation Studio). Please refer to that manual for further information. The next paragraph will only give step-by-step instructions to generate a simple building project.

To launch the building wizard, choose File / New and then select "Building Project (Multizone)"

Figure 1-29: Building Wizard Step 1: Launching the building wizard

The first step in defining the building is to create thermal zones and tell the wizard which zones are adjacent to which others. This is done using a grid layout. Clicking in a cell of the grid will create a zone at that location. In this example, we create 3 zones in E5, E6 and F6.

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Figure 1-30: Building Wizard Step 2: Zones layout

The representation uses squares independently of the real shape of the building. In our case, the real shape of the building (which can be refined later in TRNBuild) is different from the simplified "square grid" view.

The 3rd_{step is to enter the dimensions of each room:}

• Zone E5: Width = 6, Depth = 9, Height = 3 • Zone E6: Width = 6, Depth = 6, Height = 3 • Zone F6: Width = 12, Depth = 6, Height = 3

Figure 1-31: Building Wizard Step 3: Room dimensions

We can then set the glazing fraction of each side of the building (to be distributed equally among all zones) and a global rotation angle for the building (with respect to due North). The weather data file also selected. All those parameters can be changed later, once the project is created. The building in this example has 10% glazing fraction for the North side, 25% for East and West and 50% for South. "North" is actually 25° East of North.

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Figure 1-32: Building Wizard Step 4: Building orientation and glazing

We can now define the infiltration and ventilation. In this example, infiltration is 0.2 vol/h at all times and ventilation is 1 vol/h when the building is occupied (0 else).

Note: the building uses a default schedule for occupancy. All schedules can be modified later in TRNBuild)

Figure 1-33: Building Wizard Step 5: Infiltration and ventilation

This building has heating and cooling. Set points, maximum power and other characteristics are defined in step 6. We will use the default values except for the cooling set point (constant value of 26°C).

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Figure 1-34: Building Wizard Step 6: Heating and Cooling Internal gains use the default values.

Figure 1-35: Building Wizard Step 7: Internal gains

The last two steps of the building wizard allow us to define shading devices. Step 8 is used to define fixed shading devices (overhangs and wingwalls). We only define an overhang on the South side of the building. The dimensions of the window (height = 2 m, width = 13.5 m) approximate the real windows as one big window. We assume that equivalent window is shaded by a 0.5-m overhang that is attached 0.1 m above the window.

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Figure 1-36: Building Wizard Step 8: Fixed shading

Movable shadow is only used on the South side of the building as well. We keep the default values for thresholds and shaded coefficients.

Figure 1-37: Building Wizard Step 9: Movable shading

We can now generate the TRNSYS project. The building wizard will generate a TRNSYS Project and a Building Description file (.bui). It calls TRNBuild to generate the associated building files, and then opens the created project in the Studio.

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Figure 1-38: Building Wizard Step 10: Generating the TRNSYS Project

The TRNSYS project created by the building wizard has all the necessary components and the connections have been created for you. You can explore them by double-clicking on any component or link.

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1.6.2. Using the 3D Building Project

To launch the 3D building project wizard, choose File / New and then select "3D Building Project (Multizone)"

Figure 1-40: 3D Building Wizard Step 1: Launching the 3D building wizard

In the next step you will be asked to choose the 3D drawing file (*.idf) for importing.

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The wizard reads in the *.idf file that you chose and based on the information therein, generates a building description file (*.bui) and a TRNSYS Project File (*.tpf); a fully functional TRNSYS simulation is set up and the required links are generated.

Figure 1-42: TRNSYS Project File with automatic links

1.6.3. Modifying the wizard-generated project

This section will briefly illustrate how you can modify the project generated by the building wizard. You can modify the building itself but also change or add components in the simulation.

First, we will shorten the simulation period: you can run the simulation for the first week of July (hours 4344 to 4512) by changing the "Start" and "Stop" times in global control cards (accessed through Assembly/Control Cards or using the document icon circled in Figure 1-43.

You can change the online plotter axis limits by double-clicking on its icon and changing the parameters (see in Figure 1-43). Set the temperature axis limits of the online plotter to 20 and 40.

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Figure 1-43: Changing the simulation start and stop and the online plotter configuration Turn cooling off by opening the Equation Editor for "Cooling" and setting the "T_COOL_ON" variable to 50 °C (see Figure 1-44); in effect, this raises the cooling set point temperature high enough that cooling will never be engaged.

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Figure 1-44: Turning off cooling

Run the simulation and take a look at the plotted temperatures (see Figure 1-45).

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Now we are going to make some changes to the building and study the influence on the results. To edit the building, right-click on the Building icon and selecting "Edit Building". This will launch TRNBuild (see Figure 1-46).

• Select Zone F6.

• The South wall is of Type OUTWALL and has an area of 36 m² (including 18 m² of glazing). Its orientation is SHADSOUTH.

• Change the wall orientation to SOUTH. This will change the incident radiation for the wall and the included windows, effectively removing the overhang and movable shading effects. • Change the wall area to 35 m².

Figure 1-46: Wizard-generated building in TRNBuild

Save the file. Go back to the TRNSYS Studio by closing TRNBuild and run the simulation again (press F8). The temperature in zone F6 increases dramatically as far more solar gains enter the zone (larger window area and no shading). Figure 1-47 shows both results on the same graph (This is an edited picture; it is not possible to show successive runs simultaneously in the online plotter).

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Figure 1-47: Temperatures before and after changing the South wall / window in zone F6 Before

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1.7. Using TRNEdit and creating a

distributable (TRNSED) application

This section explains how to create a simple TRNSYS-based redistributable application using the Simulation Studio and TRNEdit / TRNSED.

Note: Redistributable stand-alone applications based on TRNSYS, known as TRNSED Applications, are subject to a special license agreement. The basic terms of the agreement is that you have the right to distribute those applications free of charge and that you have to negotiate a contract with the TRNSYS developers if you want to sell those applications. Please contact your TRNSYS Distributor if you have questions about licensing.

Some distributors may not activate the "Create TRNSED" function by default. If it is the case, the "TRNSED/Create distributable" menu item will be disabled in TRNEDit. You should contact your distributor to activate it.

1.7.1. Starting point: TRNSYS Studio project

Open Examples\TRNSED\SDHW-TRNSED (Studio).tpf. This is a slightly modified version of the SDHW example. The modifications are listed here below. They are already made in the project distributed with TRNSYS. If you want to repeat the whole process, please replace Examples\TRNSED\SDHW-TRNSED (Studio).tpf with a fresh copy of Examples\SDHW\SDHW.tpf

Set "Write TRNSED Commands" to "true" and change the deck file name in Control Cards. The deck filename should say: SDHW-TRNSED (Studio).trd. TRNSED applications must have a .trd extension.

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TRNSED will present a simplified view of the projects, with only some of the parameters available to users. You need to select those parameters by keeping them "unlocked", while you "lock" all other parameters to hide them.

This is done by opening the proformas of all components in the simulation and clicking on the lock icon for the corresponding parameters. It is also possible to lock all parameters of one component by clicking on the lock icon in the upper left corner of each tab. You must lock all fields in the Studio that you don't want users to be able to change. This includes parameters but also initial values for inputs and derivatives, and filenames (see Figure 1-49 for an example).

Figure 1-49: Locking parameters, initial input values, file names, derivatives initial values In this case, we will let users change the weather data file used, the solar collector slope and azimuth (Set in Type 15, the weather data processor), the solar collector area, the tank volume and the set points for auxiliary heating and for domestic hot water after the mixing valve. All other input fields should be locked (not all windows are shown in Figure 1-49, you need to double-click on every single component in the simulation).

Once all the "lock-unlock" settings are correct, you can generate the TRNSYS input file (the TRNSED deck in this case) by using "Calculate / Create input file" or using the "pen" button.

Note: This will re-create SDHW-TRNSED (Studio).trd, which you can use as a working copy for the following. The final TRNSED file after editing is saved in SDHW-TRNSED.trd. You can use this second file to examine the changes without actually performing them

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1.7.2. Editing the TRNSED file in TRNEdit

After creating the file, launch TRNEdit and open it. TRNEdit recognizes that the input file is a TRNSED file by its extension and by the "*TRNSED" command that is included by the Studio. TRNEdit creates two tabs, one displaying the source code of the input file, the other displaying the TRNSED view of the file. Both tabs are shown in Figure 1-50.

Figure 1-50: Opening the input file in TRNEdit: the Source tab and the TRNSED view

By flipping back and forth between the two tabs, you can immediately see the impact of your changes to the source code in the TRNSED view.

1.7.2.1. Rules for editing TRNSED files

All TRNSED statements start with " *| ". The first character (*) makes sure that TRNSYS will ignore those instructions (lines starting with a * and all characters after an exclamation mark are ignored by TRNSYS).

The first few lines of the TRNSED file set the title and first comment block. You can edit it to match the following lines (modified text is in bold):

*|[HEADER|

*|*Solar Domestic Hot Water System *|<STYLE1> BOLD

*|<COLOR1> NAVY *|<SIZE1> 12

*|* TRNSYS input file: SDHW-TRNSED (Studio).trd *|* A simple TRNSED demo

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A few TRNSED instructions illustrated here are:

• Groups: They are surrounded by a black border to identify a group of settings that go together but they also serve other purposes (e.g. a group can be turned on or off by TRNSED controls). A group has a name for TRNSED controls (no blanks) and a title that is displayed in the TRNSED view (if that name is blank, no title is displayed, as it is the case here). A group starts with:

*|[GroupName|Group title and ends with

*|]

• Text Style properties such as *|<COLOR1> RED. This command sets the color of

comments. You can use usual color names or any color by specifying values for Red, Green and Blue levels (1 to 255) with the following syntax (the numbers here below will result in the darker red used in the SEL logo):

*|<color1> rgb(204,0,0)

Other instructions are *|<STYLE1> (e.g. bold, italic), *|<ALIGN1> (left, center, right). • Comments: They start with *|*. The text after that is just displayed by TRNSED

We can create additional groups in the file (e.g. one for each component). The section about Type 15 (Data reader and weather data processor) is

*|*

*|* *** Model Weather (Type 15, Unit 2) *|*

CONSTANTS 2

*|*PARAMETERS

SLOPEOFS=45

*|Slope of surface |degrees|degrees|0|1|-360|360.000|1000

AZIMUTHO=0

*|Azimuth of surface |degrees|degrees|0|1|-360|360.000|1000

UNIT 2 TYPE 15 Weather

*$UNIT_NAME Weather

*$MODEL \Program Files\Trnsys16_1\Studio\Proformas\Weather Data Reading and Processing\Standard Format\TMY2\Type15-2.tmf

*$POSITION 103 129

*$LAYER Weather / Data Files # Weather - Data Files #

PARAMETERS 9

2 ! 1 File Type

39 ! 2 Logical unit

3 ! 3 Tilted Surface Radiation Mode

0.2 ! 4 Ground reflectance - no snow 0.7 ! 5 Ground reflectance - snow cover

1 ! 6 Number of surfaces

1 ! 7 Tracking mode

SLOPEOFS ! 8 Slope of surface

AZIMUTHO ! 9 Azimuth of surface

*** External files

ASSIGN "..\..\Weather\Meteonorm\Europe\CH-Zuerich-Kloten-66700.tm2" 39

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You can edit it to remove unnecessary comments inserted by the Studio (Those comments are useful if the deck file was to be re-imported in the Studio) and to enclose all input fields related to this component in a group called "LOCATION".

*|[LOCATION|Location

CONSTANTS 2 SLOPEOFS=45

*|Slope of surface |degrees|degrees|0|1|-360|360.000|1000

AZIMUTHO=0

*|Azimuth of surface |degrees|degrees|0|1|-360|360.000|1000

UNIT 2 TYPE 15 Weather PARAMETERS 9

2 ! 1 File Type

39 ! 2 Logical unit

3 ! 3 Tilted Surface Radiation Mode

0.2 ! 4 Ground reflectance - no snow 0.7 ! 5 Ground reflectance - snow cover

1 ! 6 Number of surfaces

1 ! 7 Tracking mode

SLOPEOFS ! 8 Slope of surface

AZIMUTHO ! 9 Azimuth of surface

*** External files

*|? Which file contains the TMY-2 weather data? |1000

After making similar changes to include all individual components in groups, you will get the TRNSED view shown in (The result after all the editing work is saved in Examples\TRNSED\SDHW-TRNSED (Studio).trd)

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Figure 1-51: TRNSED view after creating groups

Note: If you forgot to "lock" some parameters in the Simulation Studio or if you want to hide additional parameters, it is easy to remove the TRNSED Statements without modifying the TRNSYS statements by deleting the lines starting with "*|" or commenting them out. This is easily done by adding a second "*" in front of the "|". The statements here below will display an input field for the Collector slope and another one to select the weather data file:

SLOPEOFS= 4.5000000000000E+01

*|Slope of surface |degrees|degrees|0|1|0|90.000|1000

…

*|? Which file contains the TMY-2 weather data? |1000

The modified version here below is the same as far as TRNSYS is concerned but will not create the TRNSED input fields:

SLOPEOFS= 4.5000000000000E+01

**|Slope of surface |degrees|degrees|0|1|0|90.000|1000

…

**|? Which file contains the TMY-2 weather data? |1000

1.7.3. Some refinements

1.7.3.1. Adding an input field

There are a few things we can do to improve the usability of our TRNSED demo:

We can add a parameter that is the daily load. That parameter is set by an equation block in the simulation and the Studio did not create an input field for it.